Recycling of cotton apparel waste and its utilization as a thermal insulation layer in high performance clothing

Recycling and converting textile waste into value-added products with enhanced functional properties pave the way toward a circular economy for sustainability. This research investigates the utilization of recycled cotton fiber from apparel cutting waste for fabricating high-performance thermal barrier fabrics. The physical characterization of the developed fabrics revealed a regular arrangement of fibers, consequently the uniform thickness of the fabric with no distortion on fiber surfaces due to the recycling operation of cotton waste. The developed fabrics also demonstrated a high softness index and low compression and bending average rigidity compared to the commercial fabric with similar thickness. The heat protection performance revealed an increase in fabric conductive and radiative heat resistance with increasing the amount of recycled cotton fiber in the fabrics. The inherent thermal resistance of cotton fiber and the low inter-fiber spacing because of their uniform orientation in the fabric lead to the high thermal resistance of developed fabrics. In the case of fabric air permeability concerning the clothing thermal comfort, no significant difference in breathability was observed among the test specimens. Besides, the moisture management profile of developed fabrics indicated the capability to create favorable thermal comfort within the clothing-skin microenvironment because of improved liquid transportation and diffusion of perspiration vapor through the fabric.

Automated summary

Recycling and converting textile waste into value-added products is crucial for achieving a circular economy and sustainability. This study focuses on utilizing recycled cotton fiber from apparel cutting waste to create high-performance thermal barrier fabrics. The developed fabrics show uniform thickness and regular arrangement of fibers, resulting in high softness and low rigidity. The inclusion of recycled cotton fiber increases the fabric's conductive and radiative heat resistance. Furthermore, the developed fabrics exhibit good breathability and moisture management, enhancing thermal comfort.